Final Evaluation of the SESAR Joint Undertaking …Written by: Paul Ravenhill, Tatjana Bolic Expert...
Transcript of Final Evaluation of the SESAR Joint Undertaking …Written by: Paul Ravenhill, Tatjana Bolic Expert...
-
Written by: Paul Ravenhill, Tatjana Bolic Expert group: Tatjana Bolic, Paul Ravenhill, Helge Pfeiffer, Michael Dooms, Heather Allen June – 2017
Final Evaluation of the
SESAR Joint Undertaking (2014-2016) operating under the SESAR 1 Programme (FP7)
Final Report
-
2
EUROPEAN COMMISSION
Directorate-General for Mobility and Transport
Directorate E – Aviation Unit E3 Single European Sky
Contact: Octavian Vasile
E-mail: [email protected]
European Commission B-1049 Brussels
mailto:[email protected]
-
EUROPEAN COMMISSION
Directorate-General for Mobility and Transport Single European Sky
2017 EUR EN PDF/Volume_01
Final Evaluation of the SESAR Joint Undertaking
(2014-2016) operating under
the SESAR 1 Programme (FP7)
Final report
-
4
LEGAL NOTICE
This document has been prepared for the European Commission however it reflects the views only of the
authors, and the Commission cannot be held responsible for any use which may be made of the information contained therein.
More information on the European Union is available on the Internet (http://www.europa.eu).
Luxembourg: Publications Office of the European Union, 2017
ISBN 978-92-79-70192-4 doi: 10.2832/96511
© European Union, 2017 Reproduction is authorised provided the source is acknowledged.
Europe Direct is a service to help you find answers
to your questions about the European Union.
Freephone number (*):
00 800 6 7 8 9 10 11
(*) The information given is free, as are most calls (though some operators, phone
boxes or hotels may charge you).
http://europa.eu.int/citizensrights/signpost/about/index_en.htm#note1#note1
-
5
Table of Contents
1. EXECUTIVE SUMMARY ............................................................................................ 8
2. INTRODUCTION ................................................................................................... 13
2.1. Purpose of the evaluation ............................................................................ 13
2.2. Structure of the report ................................................................................ 13
3. BACKGROUND TO THE INITIATIVE ......................................................................... 15
3.1. Description of the initiative, objectives and relevance ...................................... 15
3.2. Baseline .................................................................................................... 21
4. EVALUATION QUESTIONS ..................................................................................... 24
5. METHOD/PROCESS FOLLOWED .............................................................................. 26
5.1. Process/Methodology .................................................................................. 26
5.2. Sources of information ................................................................................ 26
5.3. Limitations – robustness of findings .............................................................. 27
6. IMPLEMENTATION OF SESAR JOINT UNDERTAKING ................................................. 28
6.1. Membership of the SJU ................................................................................ 28
6.2. Budget and Final Outcome ........................................................................... 32
6.3. The SESAR1 Work Programme ..................................................................... 32
7. ANSWERS TO THE EVALUATION QUESTIONS........................................................... 41
7.1. Main achievements and effectiveness of implementation .................................. 41
7.2. SESAR Joint Undertaking’s performance in 2007 - 2016 .................................. 46
7.3. EU Added Value .......................................................................................... 51
7.4. Coherence ................................................................................................. 52
7.5. Relevance .................................................................................................. 56
8. CONCLUSIONS .................................................................................................... 58
9. RECOMMENDATIONS ............................................................................................ 61
10. REFERENCES ....................................................................................................... 63
11. ANNEX A: ACRONYMS .......................................................................................... 66
12. ANNEX B: SESAR1 WORK PACKAGE DESCRIPTIONS ................................................. 69
12.1. Overview ................................................................................................... 69
12.2. WP3 Validation Infrastructure Adaptation and Integration ................................ 69
12.3. WP4 En-Route Operations ............................................................................ 69
12.4. WP5 TMA Operations ................................................................................... 69
12.5. WP6 Airport Operations ............................................................................... 69
12.6. WPs 7 and 13 Network Operations ................................................................ 70
12.7. WP8 Information Management ..................................................................... 70
12.8. WP9 Aircraft Systems .................................................................................. 70
12.9. WP10 En-Route and Approach ATC Systems ................................................... 71
12.10. WP11.01 Flight Operations Centre ................................................................ 71
12.11. WP11.02 Meteorological Information Services ................................................ 71
12.12. WP12 Airport Systems ................................................................................. 71
12.13. WP14 SWIM Technical Architecture ............................................................... 72
12.14. WP15 Non Avionic CNS System .................................................................... 72
12.15. WP16 R&I Transversal Areas ........................................................................ 72
12.16. WPB Target Concept and Architecture Maintenance ......................................... 72
12.17. WPC Master Plan Maintenance ...................................................................... 72
12.18. WPE Long Term and Innovative Research Programme ..................................... 73
-
6
13. ANNEX C: SESAR1 SOLUTIONS ............................................................................. 74
13.1. SESAR Solutions ......................................................................................... 74
13.2. High Performing airport operations ............................................................... 75
13.3. Advanced air traffic services ......................................................................... 82
13.4. Optimised ATM network services .................................................................. 88
13.5. Enabling aviation infrastructure .................................................................... 90
14. ANNEX D: BIBLIOGRAPHY ..................................................................................... 95
14.1. Legislation ................................................................................................. 95
14.2. Previous Evaluations ................................................................................... 96
14.3. SJU Annual Reports..................................................................................... 96
14.4. Audit Reports ............................................................................................. 96
14.5. SJU Planning and Management Documents .................................................... 97
14.6. SJU Deliverables ......................................................................................... 98
14.7. External References .................................................................................... 98
15. ANNEX E: INTERVIEWS ........................................................................................ 99
16. ANNEX F: RESULTS OF THE STAKEHOLDER SURVEY ............................................... 100
16.1. Context .. ................................................................................................ 100
16.2. Part A: Respondents, Familiarity with SESAR and Role in SESAR ..................... 100
16.3. Part B: European Added Value .................................................................... 102
16.4. Part C: Openness - Transparency ............................................................... 104
16.5. Part D: Relevance, Coherence and Effectiveness ........................................... 106
16.6. Part E: Efficiency ...................................................................................... 111
16.7. Part F: Overall .......................................................................................... 113
17. ANNEX G: RESULTS OF THE PROJECT COORDINATORS SURVEY .............................. 115
17.1. Context .. ................................................................................................ 115
17.2. Part A: Information About You .................................................................... 115
17.3. Part B: Application process ........................................................................ 117
17.4. Part C: Grant finalisation phase .................................................................. 120
17.5. Part D: Communication and interaction with you .......................................... 122
17.6. Part E: Overall performance of JU ............................................................... 124
17.7. Part F: Overview of the project(s) objectives and impacts .............................. 127
17.8. Part G: Level of satisfaction with the content of the programme ..................... 129
-
7
Abstract
This report is the final evaluation of the SESAR Joint Undertaking (SJU) in executing the
SESAR1 programme from 2007 to 2016 as required by Article 7 of the Council Regulation
(EC) No 219/2007, amended by Regulation (EU) No 721/2014.
The evaluation was conducted between January 2017 and June 2017 by a team of
independent experts and is based on expert opinion, relevant documentation, survey
results, stakeholder interviews and data analysis.
The analysis complies with the requirements of the revised evaluation guidelines of the
Better Regulation Package and covers the five main evaluation criteria: relevance,
efficiency, effectiveness, coherence, and EU added value. In addition, the criteria:
openness, transparency and research quality are considered.
-
8
1. EXECUTIVE SUMMARY
Scope
This document presents the results of an evaluation of the SESAR Joint Undertaking
(SJU) operating under the SESAR1 work programme during 2008 to 2016. The evaluation
was conducted by a team of independent experts from January 2017 to June 2017. The
evaluation is requested by the regulation establishing the SJU.
The following criteria were considered: relevance, efficiency, effectiveness, coherence
and EU added value with additional consideration of: openness, transparency and
research quality.
The evaluation is intended to inform the European Commission’s views on the
effectiveness of the SJU, of transport Joint Undertakings and the need for future
initiatives using Public-Private Partnership as means of promoting R&D.
What is the SESAR Joint Undertaking?
The SJU is responsible for the execution and management of the development phase of
the SESAR programme - the technological pillar of the Commission’s Single European Sky
(SES) policy.
The SES was the Commission’s response to the significant air transport delays that
plagued the 1990s. The SES legislation promotes the development, modernisation, and
harmonisation of Air Traffic Management (ATM) across Europe. Over the years SES has
developed into a performance oriented system in which the service providers (or ANSPs)
are incentivised to adopt new concepts and technologies (as well as new ways of
managing the business) to achieve the SES High Level Goals:
Increasing safety by a factor of 10;
A tripling of capacity;
A halving of unit costs; and
A reduction of the environmental impact per flight by 10%.
Achieving these goals is a critical enabler for achieving sustainable Air Transport growth
and hence growth within the wider EU economy in line with the Lisbon Agenda. The role
of SESAR is to achieve modernisation of ATM using a classic three phase approach:
Definition: In 2007 and 2008 a large industry consortia developed the first
edition of the European ATM Master Plan – a blue print for the modernisation of
ATM. It defined a new concept and the enabling systems to achieve the high level
goals.
Development: The SJU is responsible for the maintenance and execution of the
European ATM Master Plan. To do so they manage a large and complex R&D
programme that identifies and matures “solutions” required by the European ATM
Masterplan. An important element of this work is to maintain the Master Plan so
that it reflects changing needs – for example since the economic crash of 2008
the focus has been more on achieving the cost-efficient and environmental goals
rather than the capacity goal which was considered critical in 2007.
Deployment: Ensuring that the delivered solutions enjoy widespread
implementation leading (alongside other developments in the industry) to the
High Level Goals being reached. A separate but interrelated arrangement – the
SESAR Deployment Manager - is responsible for the Deployment Phase.
These phases now constitute a continuous ATM modernisation lifecycle that includes
regular updates of European ATM Master Plan to ensure that the overall SESAR
programme remains relevant to the challenge of achieving the SES High Level Goals.
The current evaluation only considers the role of the SJU as the manager of the
Development Phase.
-
9
What are the main achievements to date?
For SESAR1, the SJU was established as an “EU-body” subject to EU Financial
Regulations with an overall budget of €2.1Bn (in equal parts from the Commission,
EUROCONTROL and the industry partners). The major achievements of SESAR1 were:
Completion of over 400 projects, 350 validation exercises and 30,000 flight trials
leading to…
…63 SESAR Solutions (new or improved operational procedures or technologies)
of which…
…23 are mandated for deployment by the SESAR Deployment Manager under the
Pilot Common Project Regulation; illustrating a…
…A strong and leading brand for ATM modernisation both within Europe and
globally.
The success of SESAR is best illustrated by the European ATM Master Plan (SJU, 2015)
and SESAR Solutions Catalogue (SJU, 2016). These two documents define the intent and
output of the SESAR1 programme; together with the detailed results of the SESAR1
Programme (the Solution Packs) they have enabled Europe to play a leading role in
setting global standards in ICAO and in particular in the definition of the Global Air
Navigation Plan (GANP) (ICAO Doc 9750-AN/963, 2014).
The quality of the SESAR output is therefore not only illustrated by initial deployments of
SESAR solutions by the SESAR Deployment Manager but also by the deployment of
SESAR solutions on a voluntary basis both in Europe (for example Remote Towers in
Sweden and Ireland) and globally (for example Abu Dhabi are currently evaluating
implementation of both Remote Tower and Time Based Separation/EU RECAT).
What are the main findings of the evaluation?
Throughout our evaluation SJU Members and ATM Stakeholders have highlighted the
importance of SESAR, and the SJU, as a key enabler of the wider SES policy:
The SJU and its Members have formed an unprecedented public-private
partnership (PPP) that co-ordinated and concentrates effort and resources at
European level to achieve modernisation of ATM.
The Network investors (airlines, airports, ANSPs) are confident that this PPP is
delivering the necessary solutions to achieve ATM modernisation.
The partnership approach of "working together" has led to partnerships beyond
the SJU scope (e.g. COOPANS, ITec, Borealis) that are leading to operational
improvements across Europe.
Manufacturers support the SJU because it provides access to operational
stakeholders and hence improves their R&D leading to products with increased
market potential.
Whilst the wider supply chain of the manufacturers (and large ANSPs), typically
made of SMEs, is not directly represented in the SJU Membership they are active
in SESAR work programme through subcontracting arrangements and the various
forms of membership, like Associate Member. The SJU has therefore led to a wide
and inclusive participation in ATM R&D.
Overall the evaluation of the SJU under SESAR1 is extremely positive; but there is a
word of caution. Progress is not as great as originally hoped for in the definition phase,
for example key technical enablers such LDACS - the terrestrial replacement for VDL
Mode 2 have not progressed sufficiently to de-risk some of the advanced concepts.
Further, the policy of concentrating R&D in the SJU limited the opportunities for academia
in ATM R&D (due the limited budget available for WP-E). This would not be sustainable in
the long term as it would restrict the availability of trained staff for future developments.
-
10
In terms of the main evaluation criteria:
Eff
ecti
ven
ess
The SJU has been very effective in organising the activities of the SESAR
Development phase. This includes maintenance of the ATM Master Plan,
delivering the R&D programme and building European and international
links to ensure global interoperability and European leadership in ATM
solutions.
For the main part the Work Programme has been successfully executed
leading to 63 mature solutions. As expected with such a large programme
(409 projects), some notable exceptions do exist – but the overall success
rate is impressive.
Eff
icie
ncy Previous evaluations indicate that the SJU is compliant with the
Regulations and efficient as an organisation. The SJU staff have
successfully and efficiently managed a complex R&D programme in a
manner that has built a strong partnership for ATM modernisation.
This is illustrated by the SJU’s ability to simultaneously close the SESAR1
work programme and launch the SESAR2020 programme.
Rele
van
ce
The work of the SJU is assessed as having continued relevance to the ATM
Stakeholders. The SJU and its Members are a strong partnership
committed to achieving the SES High Level Goals. The successful
maintenance of the European ATM Master Plan ensures that the SJU work
programme maintains relevance as external factors evolve.
The value of SESAR as a modernisation programme is now becoming
obvious, with the successful launch of the Deployment Phase (through
SESAR Deployment Manager) leading to European-wide deployment of
SESAR solutions.
EU
Ad
ded
Valu
e
The expected leverage for SESAR1 is 1.8 The value is consistent with a
partnership – a near equal share of EU funding and private funding.
Additional EU added is achieved through the collaborative partnership of
the SJU and the momentum created for the modernisation of ATM and
reaching the SES High Level Goals.
Co
heren
ce
The activities of the SJU have been evaluated as being coherent at four
levels:
Internal – through maintenance of the Master Plan,
FP7 – though coordination with ACARE and Clean Sky,
EU- through the strong policy link with the SES and coordination with
the wider SES actors including EASA, EDA, EUROCAE and the SESAR
Deployment Manager,
Globally – through strong links with ICAO, the FAA (NextGen) and
other national and regional programmes.
Op
en
ness a
nd
Tran
sp
aren
cy
The work of the SJU is considered to be open and transparent.
The Administrative Board Minutes, Decisions, along with the accounts and
annual reports are all publicly available.
SJU publications are well received – particularly the European ATM Master
Plan and SESAR Solutions Catalogue which together define the objective
and results of the SESAR Development Phase. Each solution is supported
by a detailed set of documentation (Solution Pack) designed to support
implementation which are all publicly available.
The SJU promotes SESAR at trade shows and other public events and is
active on social media with a positive presence on LinkedIn and Twitter.
-
11
Research
Qu
ali
ty Research Quality is assessed as excellent. The SJU Members provided
world class researchers who developed high value deliverables. This is
evidenced by the uptake of SESAR solutions both in Europe and
worldwide.
What Recommendations were made?
Overall our conclusions are positive and reinforce the findings of the previous evaluations
and support the extension of the SESAR Joint Undertaking. Our analysis suggests three
potential areas of improvement. All three relate to how the activities of the SJU can
support the longer-term role of SESAR as a modernisation programme with a strong link
to the Single European Sky policy area.
Rec 1: Strengthen the “partnership approach” including links to deployment
With the launch of the SESAR Deployment Phase, the European ATM Master Plan has a
growing importance beyond being a blue print for the necessary R&D. Rather it should be
considered a strategy document for achieving the SES High Level Goals. In this regard,
the European ATM Master Plan should further strengthen inputs from:
The wider industry (whether a member of the SJU or not).
The Performance Review Body on current performance and performance short
falls.
The Network Manager on how network functions should evolve and contribute to
the SES high level goals.
The SESAR Deployment Manager in terms of the support required to achieve
widespread adoption of SESAR solutions.
EASA in terms of how solutions can be regulated (from a safety perspective).
These connections already existed, but to some extent were managed in an ad-hoc
manner. Master Plan update programmes can only benefit if the supporting activities
become even more inclusive and secure greater transparency. It is recognised that the
creation of the Master Planning Committee in SESAR2020 starts to address this issue.
Rec 2: Strengthen the “architecture” of the Master Plan to enable the
Commission to streamline deployment planning and monitoring.
The European ATM Mater Plan consists of three layers:
The Executive level which sets out the strategy for SESAR,
The Planning and architectural view which sets out how SESAR elements
contribute to the overall system; and
The Implementation view which sets out the deployment of specific elements.
Currently all three views use different language to describe the same concepts. It is
therefore difficult to assess their consistency. It is recommended that Level 2 is
reorganised around the principles of SESAR solutions and that Level 3 is streamlined to
include deployment monitoring activities of the SESAR Deployment Manager as well as
voluntary reports from stakeholders, avoiding multiple reporting. In this way, the Master
Plan can become an even more coherent tool for planning the overall SESAR deployment
and monitor its achievement.
Rec 3: Strengthen the links to academia to ensure the innovation pipeline is fed
with new ideas
As initially conceived, the SESAR Development Phase was a relatively short programme
designed mainly to mature ATM concepts and technologies to accelerate their
deployment. The focus was on concentrating the efforts of the industry (suppliers and
-
12
service providers) on the necessary development work. It was not deemed a priority to
build links to universities in order to secure a pipeline of new ideas and future workforce.
It is now clear that SESAR is a long-term programme that needs to evolve to take
account of influences beyond ATM and respond to new challenges facing the community –
for example drones, cybersecurity, big data, machine learning, and new approaches to
regulation. To achieve this, the links to academia need to be strengthened.
-
13
2. INTRODUCTION
2.1. Purpose of the evaluation
This report is the final evaluation of the SESAR Joint Undertaking (SJU) in executing the
SESAR1 programme from 2007 to 2016.
The results of this evaluation will be used to inform the European Parliament and Council,
national authorities, the research community and other stakeholders on the final
outcome of the SJU under FP7. They will also be used to improve the implementation of
the JUs in general and of the SJU in particular under Horizon 2020 and contribute to the
formulation of the 2018-2019 SJU Annual work programmes and serve as a basis for the
ex-ante impact assessment of a possible next generation JUs.
2.2. Scope of the evaluation
This final evaluation of the SJU under SESAR1 is subject to Article 7 of the (Council
Regulation (EC) No 219/2007), amended by (Council Regulation (EU) No 721/2014),
which requires the Commission to carry out, with the assistance of independent experts,
an interim evaluation on the SJU.
The analysis complies with the requirements of the revised evaluation guidelines of the
Better Regulation Package and covers the five main evaluation criteria: relevance,
efficiency, effectiveness, coherence, and EU added value with additional consideration of
openness, transparency and research quality. The evaluation questions are summarised
in Section 4.
The evaluation covers the entire period of SJU implementation of SESAR1 between 2007
and 2016 but in doing so it builds on the two previous interim evaluations published in
2010 (COWI, 2010) and 2014 (COWI, 2014). The core focus is therefore on the activities
of the SJU during the period 1st January 2014 to 31st December 2016.
The original objectives of SJU originate from the political and socio-economic situation in
2006-2007. The evaluation covers the SJU objectives, as set out in Article 1(5) of the
SJU’s basic Regulation, whilst taking into account the emerging context, for example the
impact of the financial crisis of 2008, and in particular considers the contribution of the
SJU as an instrument towards achieving the EU's Single European Sky policy objectives.
2.2. Structure of the report
The remainder of this report is structured as follows:
Section 3: Sets out the context for the evaluation by providing background
information on the SESAR Programme and the related Single European Sky Policy
Area.
Section 4: Sets out the evaluation questions.
Section 5: Describes the evaluation methodology. Details of the surveys,
reference material and interviews used to inform this evaluation are presented in
the Annexes.
Section 6: Describes the implementation of the SJU in terms of the budget,
membership and work conducted. Statistics are provided in terms of the
distribution of funds between members, Member States and research areas.
Section 7: Provides the detailed analysis in terms of Effectiveness, Efficiency,
Coherence, EU added value and Relevance.
Section 8 sets out the conclusions to the evaluation.
Section 9 provides recommendations to the SJU going forward.
Section 10 provides the references used in this report.
-
14
This report is completed by the following annexes:
Annex A: Glossary
Annex B: SESAR1 Work Packages
Annex C: SESAR1 Solutions
Annex D: Bibliography
Annex E: Interviews
Annex F: Stakeholders Survey
Annex G: Project Coordinators Survey
-
15
3. BACKGROUND TO THE INITIATIVE
The Single European Sky ATM Research (SESAR) programme is an initiative of the EU to
modernise and harmonise Air Traffic Management (ATM) in Europe. SESAR is the
technological pillar of the Single European Sky (SES). This section sets out the
background to SESAR and establishes the policy context with the SES.
3.1. Description of the initiative, objectives and relevance
3.1.1. SES and the initiation of SESAR
Following severe flight delays in the late 1990’s, the Single European Sky initiative was
launched by the European Commission to reform European Air Traffic Management. The
first SES legislative package (SES1) was drafted by the Commission in 2001 and adopted
by the Parliament and Council in March 2004, entering into force a month later.
SES1 was fundamentally a prescriptive package. It established key principles such as the
separation of service provision from regulation (hence the creation of National
Supervisory Authorities), the certification and designation of service providers and the
transposition of ICAO and EUROCONTROL1 rules in to EU law. It also established the
concept of Functional Airspace Blocks (FABs) requiring Member States to harmonise
airspace in accordance with operational requirements rather than national boundaries.
In terms of technical modernisation, the interoperability (Regulation (EC) No 552/2004)
enabled Implementing Rules (IRs) to be developed to support harmonised deployment.
Early IRs were used to ensure common implementation dates for key infrastructure such
as COTR rule2 but there was no overarching plan or architecture for modernisation.
The SESAR programme was conceived by the industry in the widest sense, with the
objective of developing a European ATM Master Plan that would enable modernisation of
ATM through a partnership approach of all stakeholders. The ATM Master Plan was
envisaged as the overarching plan for modernisation.
The Commission funded study on the creation of the SESAR JU considered the likely
benefits to be (Steer Davies Gleave, 2005):
Earlier implementation, and consequential benefits of new concepts and
technologies;
Potentially, a better phasing of projects, taking advantage of reduced
implementation times and greater focus on high-priority projects;
Lower expenditure on conventional system upgrades of legacy systems;
Lower development costs – or “better value-added” development – due to a
reduced number of parallel developments;
Lower equipage costs for aircraft operators; and
Competitive advantage for the European air transport industry.
The intervention logic is summarised in Figure 1 including the three phases of SESAR
which are explained in further detail in the next section. It should be noted that the right-
hand side of the diagram illustrates the ATM Modernisation Lifecycle that is now central
to the SESAR project. This is described in more detail in Section 3.1.5.
1 The EUROCONTROL Safety Regulatory Requirement (see http://www.eurocontrol.int/articles/src-publications)
2 Commission Regulation (EC) No 1032/2006 of 6 July 2006 laying down requirements for automatic systems for the exchange of flight data for the purpose of notification, coordination and transfer of flights between air traffic control units
-
16
Figure 1. SESAR intervention logic.
Whilst the core industry objective for SESAR was one Master Plan, agreed to and followed
by all, the Commission also set performance objectives. In his speech at the launch event
of the Definition Phase in November 2005, Vice President Jacques Barrot expressed the
objectives of the SESAR programme as (SESAR Consortium, 2008):
“to achieve a future European Air Traffic Management (ATM) System for 2020 and
beyond which can, relative to today's performance:
Enable a 3-fold increase in capacity which will also reduce delays, both on the
ground and in the air;
Improve the safety performance by a factor of 10;
Enable a 10% reduction in the effects flights have on the environment and;
Provide ATM services at a cost to the airspace users which is at least 50% less.”
These objectives became known as the SES High Level Goals. They form an integral part
of the first edition of the European ATM Master Plan (SESAR Consortium, 2008) and as
such were adopted by the Council in March 2009 (Council Decision 2009/320/EC). Their
evolution and the SESAR contribution to achieve them are central to understanding the
effectiveness, coherence and added value of the SJU.
3.1.2. The three phases of SESAR
The SESAR project consists of three distinct phases:
Definition: Defined the need the modernisation of ATM and generated the first
edition of the ATM Master Plan.
Development: R&D Programme to develop “solutions” to achieve modernisation
Deployment: Timely synchronised deployment of those solutions.
The original definition phase was initiated in 2005 as a €60 million 2-year programme co-
financed by the European Commission and EUROCONTROL and managed by
EUROCONTROL. It was performed by the Global Consortium consisting of 30 members
and 20 subcontractors covering all ATM stakeholder groups: Air Navigation Service
Providers (ANSPs), airports, airspace users and manufacturers.
-
17
Six main deliverables were produced that described the current performance and
performance needs, an operational concept and architecture to meet those needs, a
deployment sequence and master plan along with a work programme for the R&D
required to refine the proposed concept, architecture and systems (See Table 1).
Table 1. SESAR definition phase deliverables.
Milestone 1 (D1) Milestone 2 (D2) Milestone 3 (D3) Milestone 4 (D4) Milestone 5 (D5) Milestone 6 (D6)
Current Situation
Performance Needs
Concept of Operations
Deployment Sequence
ATM Master Plan
Work Programme
• Capture of
Current
Situation with
clear
identification of
Rationale
• Strengths,
Weaknesses,
Deficiencies,
Overview of
Current
Initiatives, etc.
• Expectations for Future
• Outline Vision
of Future Air
Transport
Industry & Role
of ATM
• Performance
Requirements
for Future
Network
• Identification of “Best
Practice” & Principles upon which to Build
• Concept of
Operations
• Architecture
for Future ATM
System Network
• Set of Enabling
Technologies
Identified
• Outline of Total Cost & Preliminary
Assurance that Target is Viable
• Confirmation
of Viability
(Technical,
Financial,
Institutional,
etc.)
• Options for
Deployment
Sequence &
Recommended
“Best” Approach
• Definition of Deployment
Packages (Transition from
Legacy Systems/Frame
work)
• Detailed Plan
of Actions which
All Relevant
Organisations
need to
undertake to
Implement
Changes
• Inputs to Future Business
Plans, R&T/D Plans, Risk
Assessment Regimes,
Development of Future
Management Processes, etc.
• Proposed
Management
Structure for
SESAR
Implementation
Phase
• Proposed
Structured
Lifecycle &
Methods to
Support
Implementation
• Detailed Programme of
Work for First 5 Years of
Implementation Phase
The deliverables of the definition phase provided the initial context for the work of the
SESAR Joint Undertaking; but they also defined a concept of industrial partnership to
drive harmonisation of European ATM through the adoption of a common concept and
architecture. In particular, D5 was adopted as the first edition of the European ATM
Master Plan (SESAR Consortium, 2008) and D6 (SESAR Consortium DLM-0710-001-02-
00, 2008) which contained the first draft of the SESAR definition phase work programme.
3.1.3. The role of the SESAR Joint Undertaking
The SESAR Joint Undertaking was established to “manage the activities of the
development phase” of SESAR. The role is defined in Article 1.5 of SJU Basic Regulation
(Council Regulation (EC) No 219/2007), see Text Box 1. In effect SJU has (at least) four
distinct roles:
Management of the SESAR Development Phase work programme as a Public-
Private Partnership;
Maintenance of the European ATM Master Plan;
Supporting the global interoperability of ATM;
Providing support to the European Commission and the European Parliament on
technical issues relating to the SES (in recent years this has included
Cybersecurity, Drones and Datalink as well as advice on the contents of the Pilot
Common Project).
-
18
Text Box 1. Extract from SJU Basic Regulation (Council Regulation (EC) No 219/2007).
Together, these roles emphasise the importance of the link between the work of the SJU
and wider SES policy. SESAR is not just a R&D programme; it is a transformative
programme for a critical sector in the European economy.
It is important to note that prior to the creation of the SJU, it had been envisaged that a
single body would have responsibility for both the development and deployment phases.
The SESAR Definition Phase referred to this as the “SESAR Performance Partnership”.
However, as Article 171 of the Treaty establishing the European Union (Official Journal of
the European Communities, 2002)3 was used as legal basis for the creation of the SJU,
the role was limited to the development phase – “research, technological development
and demonstration programmes”. As will be discussed in the next section, another body
– the SESAR Deployment Manager – has since been created to manage the Deployment
Phase.
This legal basis and role of SESAR is important to the evaluation. The SJU is not a Joint
Technology Infinitive (JTI). JTIs were created under the FP7 and subsequently H2020
legislation to support the Lisbon Growth and Jobs Agenda (Council Decision
2006/971/EC) and have a research focus in that they aim to increase research in their
respective fields.
The SJU is a policy oriented with the specific objective of supporting the modernisation of
ATM in Europe. It was not set up as a JTI due to its specific policy-oriented activities (EC
COM(2013) 494, 2013).
3 Pages 0033 - 0184
5. The aim of the Joint Undertaking shall be to ensure the modernisation of the European air
traffic management system by coordinating and concentrating all relevant research and
development efforts in the Community. It shall be responsible for the execution of the ATM
Master Plan and in particular for carrying out the following tasks:
— organising and coordinating the activities of the development phase of the SESAR project,
in accordance with the ATM Master Plan, resulting from the definition phase of the project
managed by Eurocontrol, by combining and managing under a single structure public and
private sector funding,
— ensuring the necessary funding for the activities of the development phase of the SESAR
project in accordance with the ATM Master Plan,
— ensuring the involvement of the stakeholders of the air traffic management sector in
Europe, in particular: air navigation service providers, airspace users, professional staff
associations, airports, and manufacturing industry; as well as the relevant scientific
institutions or the relevant scientific community,
— organising the technical work of research and development, validation and study, to be
carried out under its authority while avoiding fragmentation of such activities,
— ensuring the supervision of activities related to the development of common products duly
identified in the ATM Master Plan and if necessary, to organise specific invitations to tender.
-
19
3.1.4. SESAR and SES2
The second package of the Single European Sky legislation (SES2), adopted in 2009, was
a significant revision of SES which:
Introduced Network Manager and the concept of Network Functions.
Introduced a performance scheme to provide economic regulation of ANSPs
(including setting of targets for safety, capacity, and environmental impact).
Transformed Functional Airspace Blocks from an airspace issue to an operational
one requiring Member States to optimise service provision within FABs.
Provided a definition of Common Projects as the legal basis for “synchronised
deployment” within the SESAR deployment phase. The SESAR deployment phase
has subsequently been launched under the management of the SESAR
Deployment Manager.
SES2 also strengthened the links between SESAR and the overall SES policy. Firstly, by
inclusion of a recital requiring close coordination between SES and SESAR (see Text Box
2) and secondly through the introduction of links between the performance scheme and
the European ATM Master Plan.
Text Box 2.Extract from SES2 regulation.
Achievement of the High Level Goals requires implementation of all aspects of the SES
legislation – including deployment of SESAR solutions but also institutional and
organisational reform incentivised through the Performance Scheme. SES2 also
strengthened the social dialogue to ensure that the human dimension is taken into
account in achieving the necessary transformation. At the same time, the EASA system
was strengthened to support the safety dimension.
3.1.5. SESAR today
The role of the SESAR programme, and therefore the requirements placed on the SJU
have clearly evolved over time. At a policy level the main changes are:
The economic crisis of 2008 profoundly affected the traffic levels in Europe. It is
now projected that the doubling of traffic compared to 2005 forecast for 2020 will
not occur until at least 2040.
There is an increased awareness of the environmental impact of aviation.
Sustainable growth of air transport requires both improved aircraft and fuels (the
role of Clean Sky) but also efficient procedures (the role of SESAR).
The Deployment Phase has been successfully launched. Deployment of the first
Common project (the Pilot Common Project is underway under the management
of the SESAR Deployment Manager (SDM)). This strengthens the interface
between the Development and Deployment Phases of SESAR and increases the
(6) Council Regulation (EC) No 219/2007 of 27 February 2007 on the establishment of a
Joint Undertaking to develop the new generation European air traffic management
system (SESAR) calls for the development and implementation of an ATM Master Plan.
The implementation of the ATM Master Plan requires regulatory measures to support the
development, introduction and financing of new concepts and technologies. It should
result in a system composed of fully harmonised and interoperable components, which
guarantee high performance air transport activities in Europe. The schedule for
implementation of the single European sky should take into consideration the timescale
foreseen for the development and deployment phases of the SESAR programme as a part of the single European sky. Both processes should be closely coordinated.
-
20
importance of the Master Plan as a single reference for ATM modernisation in
Europe and the likelihood of SESAR solutions being deployed.
There is an increased focus on performance led development within the ATM
sector. SESAR solutions therefore need to respond to both EU-wide and local
performance needs.
A number of significant technological issues have emerged (for example cyber-
security, drones) that effect the required work of the SJU.
The evolution of SESAR during this period and the activation of the deployment phase
has established an ATM modernisation lifecycle that ensures, through updates the
European ATM Master Plan, that the SESAR project in general and the SJU work
programme in particular is steered towards the actions necessary to develop and deploy
the correct solutions to achieve the SES policy objectives.
The policy link for SESAR remains as crucial today as it ever was. The need for SESAR
was reinforced in the Commission Transport White Paper published in 2011 (European
Commission, 2011) and the subsequent implementation report published in 2016
(European Commission, SWD(2016)). The Commissions Aviation Strategy4 published in
December 2015 also recognises the importance of SESAR for achievement of wider air
transport goals.
This new vision of the three SESAR phases as a lifecycle was expressed in the recitals of
Regulation (EU) 721/2014 which extended the duration of the SESAR Joint Undertaking
from 2016 to 2024, leading to two distinct phases of the SESAR development phase.
Table 2. Phases of the SESAR Development Phase
Phase Dates EC Contribution Total Available Budget
Financial Rules
SESAR1 2008 - 2016 TEN-T: €350 M
FP7: €350 M
€2.1 Bn SJU (based on FP7)
SESAR2020 2015 - 2024 H2020: €585 M €1.5 Bn H2020
In December 2014, the SESAR Deployment Phase was launched by establishing the
SESAR Deployment Manager5 in accordance with (Commission Implementing Regulation
(EU) No 409/2013) with the mandate to secure deployment of the Pilot Common Project
(Commission Implementing Regulation (EU) No 716/2014).
The SESAR Programme consists of all three phases of SESAR and forms a continuous
ATM modernisation lifecycle as illustrated in Figure 2.
Figure 2: The SESAR ATM Modernisation Lifecycle6
4 https://ec.europa.eu/transport/modes/air/aviation-strategy_en
5 http://www.sesardeploymentmanager.eu/
6 https://ec.europa.eu/transport/modes/air/sesar_en
-
21
The SJU manages the R&D needed for the modernisation of ATM, culminating in mature
SESAR solutions (at TRL 6). The mature SESAR solutions are published and can be taken
up for deployment.
Core functionalities requiring synchronised deployment can be mandated using the
provisions of Commission Implementing Regulation (EU) No 409/2013 and entrusted to
SESAR Deployment Manager. The Connecting Europe Facility includes funds identified for
deployment of core functionalities and additional funds for deployment of SESAR
solutions with local benefits.
The objective of the deployment (both EU-wide and voluntary local) is to improve the
ATM performance, and to contribute to the achievement of the SES High Level Goals. As
both the development and deployment phase are progressing over time, the impact of
the external factors is assessed periodically and taken into account in the updates to the
European ATM Master Plan, thus steering the SESAR programme in order to remain
relevant in the changing environment.
The external factors influencing the programme include the technology developments
outside of the strict ATM environment, traffic demand and the actual performance of the
European ATM system. The recent years have seem rapid developments in drones,
cybersecurity issues, big data – all have been reflected in the Master Plan updates.
The urgency of deployment of some solutions depends on the need, which is created by
the traffic demand. As traffic demand depends on many factors, and as the past decades
have seen more than one slump in the demand, the traffic forecasts in Europe are
regularly updated. EUROCONTROL’s STATFOR7 forecasts are used by different ATM
stakeholders in their daily operations.
Of course, the actual performance of the system also influences the need for R&D and
consequently its deployment. SES2 introduced the network manager function and
performance scheme (including setting of targets for safety, capacity, and environmental
impact), within its performance pillar. Thus, the actual operations are managed by the
ANSPs and the Network Manager (NM) working together, and the performance of the
system is assessed by the Performance Review Body (PRB). These assessments also help
steer the SESAR programme.
3.2. Baseline
This section describes the situation before SESAR in terms of:
The ATM value chain in terms of the development of new products; and
The modes of ATM research prior to SESAR.
The purpose in doing so to further explain the need for the SESAR programme and
establish issues that SESAR was intended to address.
3.2.1. ATM Value Chain
Air Traffic Management is central to the provision of safe and efficient Air Transport. ATM
is typically provided under monopoly conditions by national Air Navigation Service
Providers (ANSPs). ANSPs were traditionally part of the Government, often with the same
organisation providing regulatory functions (this is still the case in America, where the
Federal Aviation Authority (FAA) is both regulator and service provider).
Over the last 20 years there has been a steady process of “corporatisation” of ANSPs. In
most cases the ANSP is created as a standalone organisation fully funded by the
collection of Air Navigation Charges from Airspace Users. These organisations typically
7 http://www.eurocontrol.int/statfor
-
22
remain under public ownership but there are examples where they are under private
ownership (for example NATS and NavCanada).
Whilst en-route ATM is provided as a monopoly service, there have been a number of
States who have decided to open airport Air Traffic Control (ATC) services to competition.
The most mature market is in the UK, but Spain, Germany and Norway (amongst others)
allow for some competition for ATM services.
This has led to two quite distinct markets for ATM products within Europe:
A rather static market for en-route systems such as Flight Data Processors (FDP),
Radar Data Processes (RDP) and Controller Work Positions. These systems tended
to have a lifecycle of between 10 and 20 years.
A more dynamic market for airport systems (Tower FDPs, airfield lighting
systems, surface movement guidance and control systems).
For en-route systems manufacturers tended to develop new generations under contract
to an ANSP. Each new system would be specified by the ANSP and developed as a
bespoke system, often with proprietary interfaces. This led to limited development of
products. As the market for airport ATC systems is several hundred airports across
Europe rather than 40 or so en-route ANSPs there tended to be more innovation in
airport systems.
3.2.2. ATM Research Prior to SESAR
In 2005 air transport was experiencing significant year on year growth and a fear that
delays would increase again if significant action was not taken to modernise and de-
fragment European ATM. Significant R&D was being undertaken in Air Traffic
Management. EUROCONTROL spent about €150-200 million a year on research and
development (although some of this cost covers the planning and coordination of
implementation) in the ATM sector; the Commission funding for ATM under the Fifth
Framework Programme amounted to €20.8 million between 1998 and 2002, and was
planned to support ATM by around €100 million over the 2002-2006 period; and the
European Investment Bank also contributed €390 million to support ATM in Europe
between 1999 and 2003 (Steer Davies Gleave, 2005).
The review of existing R&D by the SESAR definition phase identified 58 initiatives;
including (SESAR Consortium DLT-0507-221-00-02, 2006):
FP6 funded programmes including research on topics such as SWIM, A-SMGCS
and CDM, which were to become central to the SESAR Development Phase work
programme.
EUROCONTROL research including the PHARE8 which included research on 4D
trajectory management, which formed the basis of the concept developed with the
Definition Phase.
National Programmes which fed into the procurement plans of ANSPs. In
particular LFV in Sweden had a strong national programme.
The R&D tended to be conducted by research organisations and ANSPs, with limited
involvement from airspace users and airport operators. A core issue at the time was
application of Airborne Separation Assistance System (ASAS) within a Free Flight
environment – including delegation of separation tasks to the cockpit and how this fitted
in with the trajectory-based concepts. Without the creation of SESAR it is not clear how
the completing issues would have been resolved.
8 https://www.eurocontrol.int/phare/public/subsite_homepage/homepage.html
-
23
3.2.3. Issues for SESAR
The SESAR was intended therefore to address the following issues:
R&D fragmentation: There was no overarching R&D strategy to ensure that
solutions were developed to address specific performance needs or indeed that all
options were considered and the best taken forward.
Limited deployment: There was no coherent deployment plan that would ensure
widespread adoption of new technology.
Limited involvement: There was limited involvement from airspace users and
airport operators (as the customers of ATM) in the definition of the R&D
programmes.
-
24
4. EVALUATION QUESTIONS
This final evaluation of the SJU under SESAR1 focusses on the following aspects:
Effectiveness: The progress towards meeting the objectives set, including how
all parties in the PPPs live up to their financial and managerial responsibilities and
keep an open non-discriminatory attitude towards a wide community of
stakeholders.
Efficiency: The extent to which the SJU was managed and operated efficiently.
Research Quality: The extent to which the SJU enabled world-class research
that helped Europe to establish a leadership position globally, and how it engaged
with a wider constituency to open the research to the broader society.
In addition to the legal requirements and in order to allow meaningful comparison
between the first and the second generation JUs, these additional aspects are addressed:
Openness and Transparency: The extent to which the JUs keep an open non-
discriminatory attitude towards a wide community of stakeholders and provide
them with easy and effective access to information on the calls.
The above-mentioned main evaluation aspects are integrated in the overall evaluation
framework (addressed under different evaluation questions).
Evaluation question 1: Background, objectives and relevance of the initiative (see Section
3)
The JUs represent the stepping-stone towards setting up PPPs in research at the
European level. They bring together EU, national and private resources, know-how and
research capabilities, with the aim of addressing major issues by sharing knowledge,
achieving critical mass, scale and scope.
In this way, they help the EU to become a world leader in developing breakthrough
technologies with high innovation potential. The public-private partnership is one of the
FP7 implementation modalities where all involved partners commit to support the
development and implementation of research and innovation activities of strategic
importance to the Union's competitiveness and industrial leadership or to addressing
specific societal challenges. As a first step, the regulatory framework is analysed and
context and background information concerning the setting up of the SJU is provided.
A summary of the situation before the approval and the set-up of the SJU is presented as
well as a brief description of the initiative, its objectives and the problems it intended to
solve.
The intervention logic of the SJU setup is presented, as well as the relevance of the SJU
objectives and whether the objectives were consistent with the strategic context and with
the challenges that had been identified.
Evaluation question 2: Implementation of the SJU (see Section 6)
The analysis of the implementation of the SJU set by the (Council Regulation (EC) No
219/2007) is presented. Information about different participation patterns of European
research actors and about the distribution of funds among beneficiaries provides
important information in order to assess if the SJU has reached the main research actors
in Europe and highlight the main research and structural trends.
Evaluation question 3: Effectiveness of implementation and main achievements
(see Sections 7.1 and 7.2.2)
Evaluation of whether the establishment of the SJU and its actual operations are in line
with the Council Regulation and whether they represent a workable framework for
achieving the SJU's objectives a set out in Article 1(5) of the SJU Regulation is
addressed. The overall approach in answering this evaluation question focuses on
assessing the link between the SJU's mandate/responsibilities and objectives set in the
Article 1(5) of its legal basis, its governance and the actual activities and performance.
SJU's mission and governance. The legal basis of SJU is reviewed to analyse and
assess the SJU's progress towards meeting the objectives set for in Article 1(5) of
-
25
its basic act, including how all parties in the PPP live up to their financial and
managerial responsibilities and keep an open non-discriminatory attitude towards
a wide community of stakeholders.
Operational Effectiveness. Assessment of whether the establishment of the SJU
and its actual operations are in line with the Council Regulation establishing it and
whether they represent a workable framework for achieving the SJU's objectives
as set out in Article 1(5) of the SJU Regulation is presented.
Direct achievements. Direct achievements focus on concrete outcomes and
deliverables of the SJU's interventions. Information about different forms of direct
achievements of the SJU funded research projects is crucial to assess whether the
SJU reached its research goals. It also represents the core of an evidence-based
analysis of funded projects. Notably, the extent to which scientific outputs
produced by the SJU's interventions generated socio-economic effects and other
impacts and helped to tackle relevant societal challenges is addressed and
presented.
Evaluation question 4: – Operational efficiency (see Section 7.2.3)
Operational efficiency considers the relationship between the resources used and changes
generated, taking into account the operational efficiency indicators.
Evaluation question 5 - European added value (see Section 7.3)
The EU-added value relates to changes that can be reasonably attributed to an EU
intervention, rather than other factors, compared to what could be achieved by the
Member States alone at national/or regional levels.
Among others this assessment covers the SJU's ability to leverage additional investments
in research and innovation. Where the SJU’s ability to attract additional finance and
multiply its own, mainly EU resources, including additional activities, i.e., activities of the
industry outside the work programme of the SJU that nevertheless are in support of its
objectives is considered to be leverage effect. The leverage effect is defined as the total
amount of funds leveraged through an Article 187 initiative, including additional
activities, divided by the respective EU contribution to this initiative.
Evaluation Question 6 – Coherence (see Section 7.4)
Taking into account the objectives of the SJU, an assessment of how well the intervention
worked: i) internally within the SJU (ability to coordinate different viewpoints and
strategies within the railway sector), ii) within FP7 and iii) with other EU policies and
interventions; is presented.
Evaluation question 7 – Synthesis, conclusions and recommendations (see
Sections 8 and 9)
Synthesis of the work done under the previous tasks is presented, conclusions drawn and
recommendations provided. The judgements are based on the evidence and analysis
available, and are as specific as possible.
-
26
5. METHOD/PROCESS FOLLOWED
5.1. Process/Methodology
5.1.1. Evaluation of the Transport Joint Undertakings
The European Commission assembled a team on nine experts under Chairmanship of
Michael Dooms to perform evaluations of the three Transport Joint Undertakings (TJUs)
namely: SESAR, Clean Sky and Shift2Rail. The expert team met on four occasions
(including 2 steering group meetings with the European Commission) to ensure a
consistent approach was taken to the evaluations. However, the work of the three teams
was largely independent of each other.
5.1.2. Evaluation of SESAR Joint Undertaking
The SESAR evaluation was performed by Dr Tatjana Bolic and Mr Paul Ravenhill
supported by Mr Helge Pfeiffer (who additionally worked on the Clean Sky evaluations)
with additional material from Heather Allen on general policy and Transport Issues.
The evaluation was conducted between 17th January and 30th June 2017 and was based
solely on expert judgement and the information sources described below and in further
detail in the Annexes to this report. The structure of this report was determined by
European Commission.
5.2. Sources of information
5.2.1. Documentation
Detailed desk study of relevant documentation was performed. Material consulted
include:
Legislation relating to SES and SESAR.
SJU Documentation
Annual Reports
Single Planning Documents
Audit Reports
External Reports
A full list of the material consulted in presented at Annex D.
5.2.2. Interviews
A number of face to face and telephone interviews were conducted with:
European Commission
SESAR Joint Undertaking Staff
SESAR Members
Industry Stakeholders.
Members of the European Parliament
In total, 30 interviews were conducted between February and June 2017. A full list of
interviews is presented in Annex E.
5.2.3. Public Survey
An on-line public survey was conducted between the 8th December 2016 and 10th March
2017. The questions were developed by the European Commission before the Evaluation
Team initiated their work. The survey covered all nine Joint Undertakings operating under
Horizon 2020. There were 68 responses for SESAR JU – some of the answers are
pertinent to SESAR1. The results are presented in Annex F.
-
27
5.2.4. Beneficiary Survey
A survey prepared by European Commission was sent to the 179 organisations that
either participated in or applied for funds for SESAR1 and SESAR20202. There were 49
responses. The main results are presented in Annex G.
5.3. Limitations – robustness of findings
In general terms, the experts considered that the data collected to be sufficient for the
tasks and had no reasons to doubt the robustness of their findings based on this study
and data.
It should however also be noted that the evaluation questions are often based on
terminology from Horizon 2020 and use KPIs defined in the Horizon 2020 regulation. As
described in Section 6, SESAR1 was operated according to the SESAR Financial
Regulation and rules and some data is not available in the required form. This is
particularly true for operational efficiency.
-
28
6. IMPLEMENTATION OF SESAR JOINT UNDERTAKING
6.1. Membership of the SJU
6.1.1. Founding Members
Article 1 (1) of the Statutes of the SJU9 defines the founding members of the SJU as the
European Commission and EUROCONTROL.
EUROCONTROL is an inter-government agency responsible for the safety of air navigation
in Europe with 41 Member States10. EUROCONTROL is an important contributor European
ATM; EUROCONTROL roles include being Network Manager, provision of ATM at the
Maastricht Upper Area Control Centre and provider of considerable ATM R&D expertise
through the EUROCONTROL Experimental Centre.
6.1.2. Full Members
Full Members were selected by an open call launched on the 27th June 2007 and
completed on the 12th June 2008 when the Membership Agreements were signed11. The
15 selected members are listed in Table 3. The table also provides an indication of their
contribution to the SESAR1 programme as the value of work conducted (including EU and
Member contribution until the end of 2015).
Table 3. Members of the SJU
Member Consortia Members Sector Country Contribution
AENA ANSP Spain €45,923,587
DFS ANSP Germany €58,503,780
DSNA ANSP France €56,498,236
ENAV ANSP Italy €49,495,325
NORACON AustroControl ANSP Austria €3,962,387
Avinor ANSP Norway €5,293,191
Finavia ANSP Finland €817,623
IAA ANSO Ireland €1,493,902
Isavia ANSP Iceland €178,022
EANS ANSP Estonia €840,659
LFV ANSP Sweden €28,635,817
Naviair ANSP Denmark €3,068,399
NATS ANSP UK €43,538,701
SEAC Heathrow Airport Airport UK €291,669
Munich Airport Airport Germany €2,276,403
Frankfurt Airport Airport Germany €2,821,973
Schiphol Airport Airport Netherlands €1,494,154
Aéroports de Paris Airport France €2,404,662
Zürich Airport Airport Switzerland €2,267,906
FREQUENTIS Manufacturer Austria €24,670,950
INDRA Manufacturer Spain €109,680,983
NATMIG SAAB Manufacturer Sweden €4,803,614
SINTEF Manufacturer Norway €15,300,615
Northop Gruman Manufacturer USA €3,689,993
Indra Manufacturer Spain €6,846,469
Airtel ATN Manufacturer Ireland €473,641
9 Annex to Council Regulation (EC) 219/2007
10 www.eurocontrol.int
11 A full timeline of the membership process is presented as appendix 6 of the initial mid-term evaluation (COWI, 2010).
http://www.eurocontrol.int/
-
29
Member Consortia Members Sector Country Contribution
SELEX Manufacturer Italy €71,891,564
THALES Manufacturer France €195,089,192
AIRBUS Manufacturer France €98,128,777
ALENIA Manufacturer Italy €27,440,080
HONEYWELL Manufacturer Czech Republic €32,856,312
Figure 3 below shows the geographical distribution of SJU members, while Figure 4
depicts the contribution to SESAR per country.
Figure 3. Geographical distribution of SJU members.
Figure 4. Contribution by SJU members, per country.
-
30
6.1.3. Associate Members
The SJU established two forms of associate Members:
Associate Partner of an SJU Member – organisations that full Members felt would
be beneficial to achieving their own contribution to SESAR and who were prepared
to make a financial contribution (as opposed to sub-contractors).
Associate Partner of the SJU – organisations selected by the SJU to “fill gaps” in
the perceived capability of the membership.
Associate Partner of an SJU Member were selected by Members and endorsed by the
Administration Board in 2010 (ADB(D)-08-2010). The selected associated members are
listed in Table 4.
Table 4. Associate Members to an SJU Member
Member Sponsor Sector Country Contribution
NAV Portugal AENA ANSP Portugal €494,948
AVTECH Airbus Manufacturer
Sweden €2,730,451
Boeing Airbus Manufactur
er
USA €1,420,339
Consortium LNVL DFS, DSNA, ENAV ANSP Netherlands €436,840
SkyGuide DFS, DSNA ANSP Switzerland €689,702
ONDA DSNA Airports Morocco -
Belgocontrol DSNA ANSP Belgium €670,854
Lockheed Martin INDRA Manufacturer
USA €89,487
PANSA INDRA ANSP Poland -
NATS Services NATS EN-route ANSP UK €64,714
Milan Airport SELEX Airport Italy €150,282
THALES Australia THALES Manufacturer
Australia €3,969,713
THALES Raytheon Systems THALES Manufacturer
UK €220,733
Associate Partners of the SJU were selected by an open call (ref. SJU/LC/0055-CFP (OJ C
76, 10.3.2011, p. 15)) issued on 1st February 2011. The call was exclusively addressed to
SMEs, research organisations, universities, and institutes of higher education. The call for
proposals was divided into six lots:
Lot 1 — Information management;
Lot 2 — Network & airport collaboration;
Lot 3 — Technical service management;
Lot 4 — Airborne & CNS systems;
Lot 5 — Modelling support to validation;
Lot 6 — UAV/UAS integration in SESAR.
Following the assessment of the proposals and the endorsement of the SJU Executive
Director’s recommendation by the Administrative Board on 1st July 2011, Framework
Partnership Agreements were awarded exclusively for lots 1, 2, 4, 5 and 6 to the two
entities having received the highest scores for each of these lots. The award was
confirmed by the Administrative Board (ADB(D)-04-2011). No award was made for Lot 3.
The associate members are listed in Table 5.
-
31
Table 5. Associate members to the SJU.
Consortia Members Type Country
Mosia
(Lot 1)
SINTEF Research Org Norway
Snowflake Software SME UK
Open Geospatial Consortium (OGCE) SME Germany
No Magic Europe UAB SME Italy
Institute for Geoinformatics (IfGI) University Germany
Westfälische Wilhelms-Universität Münster University Germany
International Geospatial Services Instit SME Germany
Envitia SME UK
Carmenta Aktiebolag SME Sweden
MEKON AIS Ltd SME Scotland
AT-One
(Lot 1 and 4)
DLR Research Org Germany
NLR Research Org Netherlands
Optromise
(Lot 2)
The University of Nottingham University UK
University of Southampton University UK
Institutt for energiteknikk Stiftelsen SME Norway
SINTEF Research Org Norway
ACCSES
(Lot 2)
Nommon SME Spain
ALG-Europraxis SME Spain
INSISOC University Spain
University of Trieste University Italy
MAGNITUDE
(Lot 4)
Becker Elektronic Polska (BEP) SME Poland
Telerad SME France
ENAC (Ecole Nationale de l’Aviation Civile) University France
ONERA/ Research Org France
CIRA - Centro Italiano Ricerche Aerospaziali Research Org Italy
INTA Research Org Spain
Helileo (HLO) SME France
M3 Systems (M3S) SME France
Inster Instalaciones SME Spain
Altys Technologies SME France
AVTECH Sweden SME Sweden
Brightline Avionics GmbH (BLA) SME Germany
Becker Flugfunkwerk GmbH SME Germany
INNOVATE
(Lot 5)
Instituto Nacional de Técnica Aeroespacia Research Org Spain
ONERA Research Org France
AVTECH Sweden SME Sweden
The University Court of the University of Aberdeen (UNIABDN)
University Scotland
The University of Edinburgh (UEDIN) University Scotland
Universita' Degli Studi di Trento (UNITN) University Italy
-
32
Consortia Members Type Country
Deep Blue Srl (DBL) SME Italy
VERTAS
(Lot 5)
AERTEC Ingenieria y Desarrollos SME Spain
ISA Software Ltd SME France
Think Research Ltd SME UK
ATM Fusion
(Lot 6)
AVTECH Sweden SME Sweden
BME University Hungary
Deep Blue SME Italy
ENAC - Ecole Nationale d'Aviation Civile University France
Institutul National de Cercetari (INCAS) Research Org Romania
INTA Research Org Spain
ONERA Research Org France
Although Associate Members of the SJU represented 60 additional members including
SME and universities very little work was placed with them.
6.2. Budget and Final Outcome
The headline figure of SESAR1 was €2.1Bn comprising equal contribution from the EU,
EUROCONTROL and the industrial partners.
Table 6. SESAR1 budget.
Source of funding Budget Final
Outcome EU European Commission, FP7 (€350 M) €700 M €700 M EU - Trans-European Transport Network Programme
(€350 M)
EUROCONTROL €700 M €670 M
Industry Partners €700 M €584 M
Total €2100 M €1900 M
Industrial Partners were co-funded at a fixed rate of 50% of actual costs and paid a 5%
cash contribution to the running costs of the SJU. Membership is discussed in the next
section. The final outcome is based on SJU estimates; final figures will not be available
until the end of 2017.
6.3. The SESAR1 Work Programme
A total of 409 projects and demonstration activities were conducted in SESAR1 under the
FP7 and TEN-T Framework programmes. This included:
322 Industrial Research and validation projects conducted by the members using
the BAFO process,
45 Exploratory research projects (selected by open tender). Conducted as WP E
these were long term and innovative research projects related to the typical scope
of FP7 projects,
42 Demonstration activities (selected by open tender).
-
33
6.3.1. Industrial Research and Validation Projects
The core work programme (see Figure 5) was designed in the SESAR definition Phase
around four key threads: Operational, System, System Wide Information Management
(SWIM) and Transversal (SESAR Consortium DLM-0710-001-02-00, 2008). The main
work packages are described in Annex B.
Figure 5. SESAR Programme (source (SJU, 2014a))
The 322 industrial research projects were conducted by the SJU Members based on the
“Best and Final Offer” (BAFO) process. In total, there were three BAFOs for SESAR1 as
summarised in Table 7.
Table 7: Summary of the BAFO Process12
BAFO Timeline Scope Approx. Projects
EU Funding Committed
BAFO1 Dec 2008 to
Mar 2009
WPB (Target Concept and Architecture)
WP3 (Validation Infrastructure),
WP4 (En-Route Operations),
WP5 (TMA operations),
WP6 (Airport Operations),
WP8 (Information management),
WP9 (Aircraft),
WP10 (En-Route & Approach ATC
Systems),
WP12 (Airport Systems),
WP14 (SWIM Technical Architecture),
WP15 (Non Avionic CNS System).
~200 ~€500M
BAFO2 July 2009 to
Dec 2009
WP C (Master Plan Maintenance),
WP 7 (Network Operations),
WP 13 (Network Information
Management System)
~100 ~125
12 Derived from SJU Annual Activity Report 2009 (SJU, 2010) and SJU Annual Activity Report 2013 (SJU, 2014)
-
34
BAFO Timeline Scope Approx. Projects
EU Funding Committed
WP 16 (R&D Transversal Areas)
9.49 (Airborne Architecture and Avionics
Interoperability Roadmap)
46 projects and Sub-Work Packages not
allocated in IBAFO 1
BAFO3 May 2013 to
Dec 2013
Reallocation of funds to priorities stemming from update to the ATM Master Plan including:
P15.01.07 – “CNS System of System
Definition”
P15.04.02 – “Integrated Surveillance
Sensor P15.04.06 – “Improved 1090 MHz ADS-B
Ground Station capability & Security”
P15.02.05 – “I4D Trajectory Exchange
using SATCOM IRIS precursor”
12 Mostly Reallocation
The SJU experienced difficulty in managing the execution of more than 300 projects due to the large number of interdependencies between projects. A single project could be dependent on the outputs of many other projects often from several WPs. The principle method used to group projects during SESAR1 was the operation focus areas (OFA) which fundamentally grouped the projects delivering performance improvements in specific areas. The 31 OFAs are listed in
Table 8 along with the level of investment in SESAR1.
Table 8: Budget per OFA
Operational Focus Area R&D investment
LVPs using GBAS €51.288.749
Pilot enhanced vision €10.097.791
Airport safety nets €33.501.191
Enhanced Runway Throughput €58.229.089
Optimised 2D/3D Routes €18.063.394
Free Routing €61.412.494
Business and Mission Trajectory €32.254.709
ASAS Spacing €26.444.041
ATSA-ITP €7.876.950
ASEP €14.857.108
Ground Based Separation Provision in En Route €32.688.151
Ground Based Separation Provision in the TMA €28.331.893
Enhanced Ground Based Safety Nets €8.154.975
Enhanced ACAS Operations €9.787.250
Integrated Arrival/Departure Management at Airports €21.563.069
Enhanced Arrival & Departure Management in TMA and En Route €62.074.182
Integrated Surface Management €50.691.364
Airport Operations Management €41.938.689
Airspace Management and AFUA €8.591.148
Dynamic Airspace Configurations €8.980.336
Enhanced ATFCM processes €28.633.262
UDPP €13.565.056
Network Operations Planning €16.701.340
CWP Airport €27.138.732
-
35
Operational Focus Area R&D investment
CWP En Route and TMA €10.178.098
Remote Tower €20.799.502
Communication €46.473.646
Navigation €13.554.334
Surveillance €16.915.362
SWIM €53.849.627
AIM/MET €15.831.098
Trajectory Management Framework €55.765.465
Total €906.232.094
However, to communicate the results of SESAR to the wider community, the SJU and
Membership developed the concept of “Solution”. The SESAR solutions are “new or
improved operational procedures or technologies that aim to contribute to the
modernisation of the European and global ATM system” (SJU, 2017).
During SESAR1, 63 solutions were developed as summarised in Table 9. Further details
are provided in Annex C. There are a further 54 Solutions that are considered not mature
(in V1 or V2, which is lower than TRL6), which are expected to reach maturity under
SESAR 2020.
Table 9. SESAR solutions by category, and the budget spent (source: (SJU, 2016)).
Solution category Number of solutions
Number of solutions for PCP
Percent of total budget
High performing airports 21 6 28%
Advanced air traffic services 21 6 32%
Optimised ATM Network Management 8 6 24%
Enabling aviation infrastructure 13 5 17%
Out of 63 Solutions, 23 are related to the Pilot Common Project (Commission
Implementing Regulation (EU) No 716/2014, 2014). These solutions have a mandate for
deployment as described in Section 3.1.5.
6.3.1. Work package E Research projects - Exploratory Research
During SESAR1, the SJU organised two calls for Exploratory Research projects resulting
in 42 projects with grants totalling €1.6million (with an average grant size of €670k).
Table 10. WP E projects.
Project name Lead Organisation Lead Country
Lead
Organisation Sector
Total
Project Cost (€)
SJU
Funding (%)
SUPEROPT UNIVERSITY OF BRISTOL
UK University 158.000 100%
NEWO ISDEFE Spain Research Org 265.000 100%
STREAM ADVANCED LOGISTICS GROUP
Spain Research Org 453.000 100%
ONBOARD GMV Spain Research Org 411.000 100%
ASHICS UNIVERSITY OF YORK UK University 294.000 100%
POEM UNIVERSITY OF WESTMINSTER
UK University 371.000 100%
-
36
Project name Lead Organisation Lead
Country
Lead Organisation
Sector
Total Project
Cost (€)
SJU Funding
(%)
TESA LONDON IMPERIAL
COLLEGE UK University 285.000 100%
MUFASA LOCHKEED MARTIN UK UK Ground Industry 639.000 100%
ADAHR & NEWO ISDEFE Spain Research Org 625.000 100%
MAREA NLR Netherlands Research Org 650.000 100%
C-SHARE TECHNICAL UNIVERSITY DELFT
Netherlands University 842.000 100%
COMPASS THALES INFORMATION SYSTEMS
Belgium Ground Industry 737.000 100%
ALIAS EUI EUROPEAN UNIVERSITY INSTITUTE
Italy University 686.000 100%
CASSIOPEA INNAXIS Spain Research Org 682.000 100%
UTOPIA TECHNICAL UNIVERSITY DRESDEN
Germany University 962.000 100%
ZeFMaP SINTEF Austria Ground Industry 876.000 100%
SPAD DEEP BLUE Italy Research Org 730.000 100%
ELSA DEEP BLUE Italy Research Org 679.000 100%
ROBUSTATM
FRIEDRICH-ALEXANDER UNIVERSITY ERLANGEN-
NUREMBERG
Austria Research Org 673.000 86%
AGATHA ALTYS France Research Org 727.000 83%
SAFECORAM CIRA Italy Research Org 372.000 75%
NINA DEEP BLUE Italy Research Org 674.000 89%
ALIAS II DEEP BLUE Italy Research Org 690.000 87%
MOTA ENAC France Research Org 768.000 73%
6TH SENSE FRAUNHOFER AUSTRIA Austria Research Org 583.000 64%
FLITE & TESA LONDON IMPERIAL COLLEGE
UK University 666.000 86%
SECUREDATACLOUD INNAXIS Spain Research Org 760.000 78%
TREE ISDEFE Spain Research Org 674.000 66%
ACCESS NOMMON SOLUTIONS AND TECHNOLOGIES
Spain Research Org 787.000 73%
SCALES SINTEF Norway Research Org 799.000 75%
ACCHANGE TRANSPORT &
MOBILITY LEUVEN Belgium Ground Industry 760.000 79%
EMFASE UNIVERSITY TRENTO Italy University 657.000 85%
SATURN UNIVERSITY TRIESTE Italy University 594.000 100%
ERAINT
TECHNICAL UNIVERSITY OF CATALONIA - BARCELONA TECH
Spain University 622.000 80%
COMPLEXITY COSTS & POEM
UNIVERSITY OF WESTMINSTER
UK University 704.000 84%
PROGA NLR Netherlands Research Org 661.000 96%
-
37
Project name Lead Organisation Lead
Country
Lead Organisation
Sector
Total Project
Cost (€)
SJU Funding
(%)
AEROGAME NLR Netherlands Research Org 780.000 75%
ACF NLR Netherlands Research Org 656.000 81%
EMERGIA NLR Netherlands Research Org 400.000 75%
IMET NLR Netherlands Research Org 581.000 75%
6.3.2. Demonstration Projects
During SESAR1, the SJU organised 5 calls for demonstration projects resulting in 66
projects with grants totalling €94million (with an average grant size of €1.4million):
Three calls were launched to support the Atlantic Interoperability Initiative to
Reduce Emissions (AIRE), which was a joint venture with the USA to integrated
flight trials and demonstrations validating solutions for the reduction of CO2
emissions for surface, terminal and oceanic flight operations.
Large Scale Demonstrations were designed to support validation of the core
programme by providing large scale flight trials of developed solutions.
Remotely Piloted Aircraft System (RPAS) Demonstrations were designed in
investigate the integration of Unmanned Air Vehicles (UAVs) into non-segregated
and controlled airspace.
Table 11. AIRE projects.
Project Lead Organisation
Country Organisation Sector
Total Project Cost (€)
SJU Fund (%)
Ground movements AEROPORTS DE PARIS
France Airport 238.668 52%
MINT AVTECH Sweden Air Industry 200.000 50%
North Atlantic cruise climb lateral deviation and Mach number flight trials demonstration project
NAV Portugal Portugal ANSP 200.000 50%
Reduction of emissions on the North Atlantic by the implementation of ADS-B
ISAVIA Iceland ANSP 200.000 50%
RETACDA INECO Spain Research Organisation
212.800 47%
Terminal Operations DSNA France ANSP 220.000 51%
Airport CDM Project in Vienna LUF